Methods and devices for reducing CO2 to produce hydrocarbons are disclosed. A device comprises a photoanode capable of splitting H2O into electrons, protons, and oxygen; an electrochemical cell cathode comprising an electro-catalyst capable of reducing CO2; H2O in contact with the surface of the photoanode; CO2 in contact with the surface of the cathode; and a proton-conducting medium positioned between the photoanode and the cathode. Electrical charges associated with the protons and the electrons move from the photoanode to the cathode, driven in part by a chemical potential difference sufficient to drive the electrochemical reduction of CO2 at the cathode. A light beam is the sole source of energy used to drive chemical reactions. The photoanode can comprise TiO2 nanowires or nanotubes, and can also include WO3 nanowires or nanotubes, quantum dots of CdS or PbS, and Ag or Au nanostructures. The cathode can comprise a conductive gas diffusion layer with nanostructures of an electro-catalyst such as Cu or Co.
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11. An integrated photovoltaic cell and electrochemical cell, comprising:
a photovoltaic (pv) cell comprising first and second spaced apart electrodes and at least one light-receiving channel, which together comprise a photoanode, that receives a light beam, having at least one wavelength in a range of at least one of 260-600 nm and 700-1500 nm, where the channel receives at least two H2O molecules and exposes the at least two H2O molecules to the light beam and dissociates the at least two H2O molecules into at least four H+ ions, at least four electrons and at least one oxygen-containing molecule; and
an electrochemical cell, comprising the second electrode and a third electrode, spaced apart from each other by a proton-conducting electrolyte, where the third electrode has an associated positive chemical potential ΔCP relative to the second electrode and the third electrode is configured to receive at least one CO2 molecule and to permit the at least one CO2 molecule to interact with the H+ ions and the electrons, and to thereby become reduced, and to produce at least one hydrocarbon,
wherein operation of the integrated photovoltaic cell and electrochemical cell does not use a battery or equivalent source of electrical power; and
wherein said third electrode comprises at least one of Cu nanoparticles and Co nanoparticles, which are passivated with at least one of polyvinylpyrrolidone (PVP) nanoparticles, Au nanoparticles and Ag nanoparticles.
1. A system for converting CO2, to one or more hydrocarbons, comprising:
first and second photovoltaic (pv) electrodes, spaced apart and configured to provide at least one channel, defined by at least two nanostructures that are aligned approximately perpendicular to a surface of said first pv electrode, he nanostructures comprising at least one of nanotubes and nanowires, extending between the first and second pv electrodes, where at least one of the first and second electrodes comprises a conductive electrode, partly or fully transparent at a channel end, where the at least one channel receives a light beam, receives at least two H2O molecules and causes the at least two H2O molecules to dissociate into at least four H+ ions, at least four electrons, and at least one oxygen-containing molecule;
wherein the light beam has at least one wavelength in a range of at least one of 260-600 nm and 700-1500 nm;
wherein the second pv electrode also serves as a first electrochemical cell electrode (ECE) of an electrochemical cell;
a second electrochemical cell electrode (ECE), spaced apart from the first ECE and comprising an electrocatalyst that is configured to receive at least one CO2 molecule, at least four H+ ions and at least four electrons and to reduce the at least one molecule of CO2 to provide at least one hydrocarbon molecule that is at least one of CH4, C2H4 and C2H6, with a total branching ratio of at least about 10 percent; and
a proton-conducting electrolyte, positioned between and connected to the first ECE and the second ECE;
wherein the second ECE has an associated positive chemical potential relative to a chemical potential of the first ECE;
wherein the second ECE comprises nanostructures comprising at least one of Cu and C, distributed over a gas diffusion layer, the gas diffusion layer comprises at least one of (i) carbon fibers and a hydrophobic binder and (ii) an intrinsically conducting polymer that comprises polythiophene;
wherein electrical charges associated with the H+ ions and with the electrons move in the electrolyte from the first ECE toward the second ECE; and
wherein the device has no battery or other source of electrical power.
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3. The system of
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The invention described herein was made in the performance of work under NASA contract number NNX08AQ41A and is subject to the provisions of Public Law 96-517 (35 U.S.C. §202) in which the Contractor has elected not to retain title.
One or more embodiments of the present invention relate to apparatuses and methods for reduction of CO2.
The burning of carbon fuels dominates energy production and will continue to do so for the foreseeable future. Carbon sequestration is currently being pursued in an attempt to reduce CO2 emissions. However, a more elegant and long-lasting solution would be to convert emitted CO2 back into useable materials that could then be re-burned for carbon neutral energy production or used for other purposes, such as feed stock for chemical syntheses. Photosynthesis does this naturally, and programs to reduce deforestation or plant new forests and other plants have been proposed. Converting waste CO2 into usable materials at the source (such as vehicles and smokestacks) could also help. Further, there are extraterrestrial applications of CO2 conversion such as the manufacture of hydrocarbon fuels on Mars from atmospheric CO2.
Studies show that three processes, photocatalysis, electrochemistry, or photoelectrochemistry, can be used for CO2 conversion [Gattrell and Gupta, 2006]. Photocatalysis has been successfully demonstrated using photocatalysts (e.g., TiO2, ZnO and CdS). The main conversion selectivity can be challenging and depends sensitively and selectively on the properties of the photocatalysts. The products range from methane, methanol, ethylene, to formic acid and formaldehyde [Saladin et al., 1995], although the optical to chemical conversion efficiency has generally been low, less than 1 percent [Taniguchi, 1989].
Electrochemical conversion of CO2 has been based primarily on bulk metal electrodes, such as Zn, Pb, Sn, In, Cd, Cu, Au, Hg or metal alloys such as Cr—Ni—Mo. The main conversion products include formic acid, oxalic acid, methane, and hydrogen [Taniguchi, 1989]. Semiconductor electrodes TiO2 or GaAs [Monnier et al., 1980] can also generate methane and methanol, with chemical conversion levels as high as 100 percent [Canfield and Frese, 1983]. However, such an electrochemical approach requires the use of an electricity source with limited device platforms, and product selectivity is generally low.
On the other hand, photoelectrochemistry has also been demonstrated successfully in the conversion of CO2 into hydrocarbons such as methane, methanol, and ethylene, using mainly bulk p-type semiconductors as electrode materials, e.g., InP, GaAs and CdTe[Ito et al., 1984]. While the electrochemical efficiency is often high (>30 percent), the light conversion efficiency is usually low (<1 percent).
Although not heretofor applied to CO2 conversion, the idea of using solar-generated electricity to power a photoelectrochemical cell (PEC) was first proposed and demonstrated using a silicon solar cell to produce hydrogen from water in a PEC cell using a bulk TiO2 photoanode [Morisaki et al., 1976]. A more recent example using a dye-sensitized solar cell to provide power for water splitting in a PEC was described by Sivula et al. (“New nanostructures enhance solar water splitting with hematite,” SPIE Newsroom, 10.1117/2.1201007.003145,2010).
Methods and devices for reducing CO2 are disclosed. In one embodiment, the device comprises: a photoanode capable of splitting water into electrons, protons, and oxygen; a cathode comprising an electrocatalyst capable of reducing CO2; liquid or gaseous water in contact with the surface of the photoanode; CO2 in contact with the surface of the cathode; and a proton-conducting medium positioned between the photoanode and the cathode. The proton-conducting medium is an electrical insulator with low O2 permeability. The electrons flow in a conductor from the photoanode to the cathode at a chemical potential sufficient to drive the electrochemical reduction of CO2 at the cathode. Light is the sole source of power used to drive chemical reactions. The photoanode may comprise TiO2 nanowires or nanotubes, and may also include WO3 nanowires or nanotubes, quantum dots of CdS or PbS, or Ag nanowires to broaden the range of spectral absorption and enhance light conversion efficiency. The nanowires or nanotubes can be attached to either a transparent conductive electrode (e.g., indium tin oxide, fluorine doped tin oxide, carbon nanotubes, or graphene) or a conductive gas diffusion layer, preferably aligned to be substantially parallel to each other and perpendicular to the electrode surface.
The cathode may comprise a conductive gas diffusion layer with nanostructures of an electrocatalyst such as Cu dispersed thereon. The gas diffusion layer typically comprises carbon fibers and a hydrophobic binder. The cathode may further comprise a photosensitizer capable of enhancing the electrocatalytic reduction of CO2. Example photosensitizers include intrinsically conducting polymers such as polythiophene.
The proton-conducting medium can be made from NAFION®, and may also include a buffered electrolyte such as KHCO3.
A light concentrator can also be included to select and concentrate light on the photoanode.
Methods for reducing CO2 are disclosed, wherein one method comprises: providing an integrated photovoltaic electrochemical cell (iPVEC), exposing the photoanode to water and photons such that water is split into electrons, protons, and oxygen at the photoanode, reducing CO2 electrocatalytically at the cathode using the electrons generated at the photoanode. The electrons flow in a conductor from the photoanode to the cathode at a chemical potential sufficient to drive the electrochemical reduction of CO2 at the cathode.
In one embodiment, the iPVEC comprises a photoelectrochemical cell with two electrodes comprising a photoanode and a cathode, with a proton-conducting medium positioned between the two electrodes. The water can be supplied as liquid water or as water vapor (e.g., an inert gas containing water vapor). Introduction of water into an inert gas can be achieved through bubbling the gas through a container of liquid water, with or without heating. The relative humidity can be optimized to promote CO2 reduction vs. water splitting, and can be increased as demand increases (e.g., during increased supply of CO2 to the cathode).
In some embodiments, the CO2 is supplied from a device or apparatus that produces CO2 as a byproduct of combustion.
In some embodiments, the photoelectrochemical cell is able to maintain an efficiency of reducing more than 10 percent of the CO2 within a time period ranging from 1 to 100 minutes.
In some embodiments, the CO2 is supplied from a planetary atmosphere. The CO2 from the planetary atmosphere can be provided at native concentrations, provided from CO2 sequestration, or can be concentrated in a CO2 scrubber prior to being provided to the iPVEC. Gas containing CO2 can be flowed through beds of sorbent materials such as activated carbon. Once the sorbent material is saturated, the adsorbed CO2 can be desorbed via a flow of low CO2 gas such as air, or by elevating the temperature of the sorbent material in order to promote CO2 desorption. The products of CO2 reduction can be stored for use as a fuel, or reused for combustion by feeding the reduction products back into a combustion chamber in fuel cells.
Before the present invention is described in detail, it is to be understood that unless otherwise indicated, this invention is not limited to specific materials, polymers or photocatalysts. It is also to be understood that the terminology used herein is for the purpose of describing particular embodiments only and is not intended to limit the scope of the present invention.
It must be noted that as used herein and in the claims, the singular forms “a,” “and” and “the” include plural referents unless the context clearly dictates otherwise. Thus, for example, reference to “a polymer” includes two or more polymers, and so forth.
Where a range of values is provided, it is understood that each intervening value, to the tenth of the unit of the lower limit unless the context clearly dictates otherwise, between the upper and lower limit of that range, and any other stated or intervening value in that stated range, is encompassed within the invention. The upper and lower limits of these smaller ranges may independently be included in the smaller ranges, and are also encompassed within the invention, subject to any specifically excluded limit in the stated range. Where the stated range includes one or both of the limits, ranges excluding either or both of those included limits are also included in the invention. Where the modifier “about” is used, it is understood that the stated quantity may vary by up to ±10 percent. Where the modifier “substantially” is used, it is understood that the stated quantity may vary by up to ±5 percent.
As used herein, the term “CO2 conversion” or “converting CO2” refers to the electrochemical reduction of CO2, producing reduced carbon in the form of hydrocarbons, alcohols, aldehydes, acids, and the like.
As used herein, the term “PEC” refers to a photoelectrochemical cell, wherein light is absorbed on a photosensitized electrode of an electrochemical cell in a way that facilitates an electrochemical reaction. In a typical example, the photosensitized electrode is a semiconductive material such as TiO2.
As used herein, the term “PVC” refers to a photovoltaic cell which converts light to electrical power. The term is used generically to refer to any technology, whether solid state or liquid.
As used herein, the term “iPVEC” refers to an integrated photovoltaic/photoelectrochemical cell comprising both photovoltaic conversion of light to electrical energy and a photoelectrochemical cell in a unified structure.
As used herein, the term “proton-conducting medium” refers to a medium in which protons can move under the influence of an electric field or a chemical gradient. Specific proton-conducting media that are useful in embodiments of the present invention are electrical insulators that do not conduct electrons, and they are impermeable to larger atoms and molecules such as oxygen.
As used herein, the term “electrical insulator” refers to a material having little or no conductivity for electrons in the sense that any non-zero electron currents that flow through the material are much less than currents flowing by the sum of all other available paths between two reference points. In the case of proton-conducting media, there may be conduction mechanisms that do not involve electrons due to ion mobility (and specifically proton mobility due to proton conduction mechanisms).
As used herein, the term “intrinsically conducting polymer” refers to a polymer with electronic conduction (conductivity via electron mobility as opposed to ion mobility). The conduction is through the polymer itself and is not provided through the use of a conductive filler or dopant.
As used herein, the term “nanostructures” refers to any object having a size range generally between about 10 nm and about 100 nm. Some nanostructures have aspect ratios near unity and shapes that are approximately spherical or polyhedral (cubic, tetrahedral, etc.). Others such as “nanowires” have a large aspect ratio of greater than 10:1. Still others (“nanotubes”) have a tubular structure with a similar large aspect ratio, up to about 1000:1.
As used herein, the term “quantum dot” refers to an object having photosensitivity and a size less that the relevant wavelength of light. By adjusting the size of a quantum dot, the peak absorption wavelength can be tuned. Embodiments of the present invention typically use structures comprising nanowires or nanotubes with a set of much smaller quantum dots distributed over their surfaces.
As used herein, the term “gas diffusion layer” or GDL refers to a membrane or film that is highly porous to gases but impermeable to liquids. Typical examples are constructed from a disordered mat of fibers bound by a hydrophobic resin. Carbon fibers and fluorocarbon resins are commonly used. Pore sizes are typically a few microns, and gas porosity is typically at least 70 percent.
Overview
The present application discloses novel integrated photoelectrochemical devices that combine electrolysis of water at a photoanode and electrocatalytic reduction of CO2 at a cathode using only light to drive the conversions. Devices such as TiO2 photovoltaic cells, electrocatalytic cells capable of reducing CO2, and photoelectrochemical cells configured to split water are known in the art as distinct platforms and have not heretofor been integrated into a unitary device. The integrated devices have unique capabilities and applications not present in prior art devices or previously possible. These known devices are briefly described below.
Photovoltaic devices or cells (PVCs) based on TiO2 have been widely studied, although they tend to exhibit low efficiencies and have not yet been adopted for commercial solar power applications in significant quantity. Many variations are possible. Most PVCs are generally constructed as p-n or p-i-n diodes and depend on the diode structure to separate photoelectrons and holes in order to create a preferred direction for the flow of electrical current. In contrast, TiO2 PVCs are better described as photoelectrochemical cells (PECs) used to generate electrical power (Minutillo, J. et al., “Development of TiO2 Nanoparticle-Based Solar Cells,” 2008, retrieved on-line Jan. 13, 2012 from academics.adelphi.edu/artsci/bio/pdfs/) nonoparticle_based_solar_cells.pdf). The TiO2 is affixed to a transparent electrode (anode) and sensitized with a dye to provide increased photoabsorption at visible wavelengths, λ=c/ν An electrolyte with an iodide/triiodide redox couple and a counter electrode (cathode) are provided. The relevant photochemistry and electrochemistry is given by:
hν+2H2O→2H++2OH−, (1)
hν+2H2O→4H++O2+4e−, (2)
Electrochemical cells can be configured to reduce CO2 and can produce a variety of end products. CH4 production is favored when using a copper electrocatalyst (i.e., a copper-containing cathode). The reaction at the cathode is
CO2+8H++8e−→CH4 (gas)+2H2O (liquid). (3)
A suitable electrolyte containing chloride or bicarbonate provides good proton conductivity between electrodes. Normally, the electrons are supplied from an electrical power source.
A widely described application of photoelectrochemical cells or PECs is for splitting water into hydrogen and oxygen. TiO2 is frequently used as the photoanode, and the reaction is
2H2O (liquid)+hν→O2 (gas)+4H++4e−. (4)
Oxygen evolves and is collected over the photoanode. The protons travel through an electrolyte (e.g., Na2SO4, KHCO3) to a counter electrode (cathode). Electrons travel through another circuit to recombine with the protons so that hydrogen gas evolves at the cathode.
Embodiments of the present invention combine the photoelectrochemical generation of electrical power and protons (electrons and protons at useful potential differences), with electrochemical reduction of CO2 in a single unified structure, using an integrated PVC/PEC (integrated photovoltaic cell/photoelectrochemical cell or iPVEC). This device combines a photosensitive anode that splits water and generates electrical energy with an electrocatalytic cathode for the reduction of CO2. The electrodes are separated by a proton-conducting medium. In some embodiments of the invention, an iPVEC comprises a photoanode capable of splitting water into electrons, protons, and oxygen, a cathode with an electrocatalyst capable of reducing CO2, a supply of water at a surface of the photoanode, a supply of CO2 at a surface of the cathode, and an electrically insulating proton-conducting medium between the photoanode and the cathode. The proton-conducting medium allows protons to flow from the photoanode to the cathode but is impermeable to larger atoms and molecules such as oxygen and water. Electrons generated at the photoanode are allowed to flow to the cathode by another route, where the electrons provide the necessary electrical power for the electrocatalytic reduction of CO2. The components and arrangement of components are described in greater detail below.
Integrated Photovoltaic/Photo Electrochemical Cells
The various functions of power generation, water splitting, and CO2 reduction can be integrated into a single device using a variety of specific hardware configurations. Integration can serve to minimize device size, share hardware, share operating functions, and provide self-regulation. In some embodiments, a PVC is used to provide the electrical power to drive an electrochemical cell configured to reduce CO2. The PVC can be a TiO2-based PEC, although other PVCs can also be used. Mechanical integration can be implemented, for example, by sharing one electrode such that one electrode of the PVC serves as an electrode of the electrochemical cell. The two devices can be constructed in planar form and can have the same area. As long as the open-circuit voltage of the PVC exceeds the potential required to drive the electrochemical reaction, CO2 can be reduced. The rate of CO2 reduction is determined by the supply of CO2 and the available current from the PVC.
In some embodiments, further integration can be achieved by using a water-splitting PEC instead of a closed-cycle PVC that generates only electrical power. In these embodiments, the incoming light energy is used to split water to form protons, electrons, and oxygen. The oxygen can be collected as a byproduct or vented. Water can be provided in liquid or gaseous form. Where large-area small-thickness designs are preferred, supplying the water in gaseous form can be preferable, because less pressure and structural strength can be sufficient to drive water through the device at adequate flow rates, although both liquid and gaseous embodiments are possible.
Both the electrons and protons produced from the water splitting reactions can be provided to the electrochemical cell to enhance the reduction of CO2 using, for example, the reaction in Eq. (3). In some embodiments, the water-splitting photoanode is separated from the electrocatalytic cathode by a proton-conducting medium. A current path is also provided for electrons to flow separately from the photoanode to the electrocatalytic cathode. In accordance with the reactions in Eqs. (3) and (5), for every CO2 molecule reduced, there is a net consumption of 4 H2O molecules in the PEC, a net production of two O2 molecules in the PVC, and a net production of one CH4 molecule and two H2O molecules in the electrochemical cell.
Two exemplary embodiments of an iPVEC using a proton-conducting medium are shown in
In the embodiment of
In the embodiment of
The photoanode depicted in
The liquid and gas flow chambers 220 and 222 shown in
Photoanodes
The photoanode can comprise photoactive materials such as semiconductors that can generate photoelectrons (e−) in the conduction band and holes (h+) in the valence band of the semiconductor. Typical semiconductors that are useful as photoanodes include TiO2 or mixtures of TiO2 and WO3, and the like. In some embodiments, the photoanode comprises TiO2 nanowires or nanotubes, and can also comprise sensitizers to improve light absorption at particular wavelengths. TiO2 absorbs predominately ultraviolet (UV) light (<˜400 nm wavelengths), and higher wavelength light is allowed to pass through. This embodiment can be preferred in environments where UV light is abundant (e.g., high altitude, space, Mars surface). Sensitizers can include dyes, quantum dots, and the like. These sensitizers absorb light at additional wavelengths such as visible (˜400-750 nm) and infrared wavelengths (>˜750 nm). The sensitizers can be distributed over the surface of the nanowires or nanotubes. Suitable quantum dots can be made from a variety of photosensitive materials including PbS, CdS and CdSe. Their size can be adjusted to optimize wavelength sensitivity to match the wavelength of available light, for example, the quantum dot diameters may be 2-10 nm.
The performance of the photoanode can be further enhanced by including WO3 nanowires or nanotubes that have different wavelength sensitivity from TiO2. Further, “plasmonic enhancement” can be provided by including nanowires of a reflective metal such as Ag. Such reflective nanowires can serve to increase the light delivered to light absorbing elements of the photoanode.
In some embodiments, the nanowires or nanotubes are physically and electrically connected to a transparent conductive electrode. It can be beneficial to arrange the nanowires or nanotubes so that their ends are attached to the transparent conducting electrode and substantially parallel to one another. This arrangement can improve the collection of photons and electrons by the nanowires or nanotubes, reduce light scattering, and deliver electrons to the electrode. Any suitable transparent conductive electrode can be used such as those made from indium tin oxide, fluorine-doped tin oxide, doped zinc oxide, carbon nanotubes, graphene, and the like.
Electrocatalytic Cathodes
The electrocatalytic cathode comprises an electrocatalyst on a conductive support. In some embodiments the cathode comprises nanostructured catalytic particles dispersed over the support. A convenient support is a gas diffusion layer (GDL) such as the carbon paper commonly used in fuel cells. Suitable carbon papers are made from disordered mats of carbon fibers, typically with a hydrophobic binder such as TEFLON® or other fluorocarbons. Typical properties include high porosity (˜80 percent), pore sizes in the range of about 1-10 microns, and moderate electrical conductivity such that the carbon papers can be used as electrodes without significant voltage drop across the material. Carbon paper GDLs can be used as a conductor to form the cathode, and can also serve as a support for an electrocatalyst. In some embodiments the support further comprises a metal oxide such as zinc oxide, optionally in the form of nanostructures such as nanowires. Zinc oxide also has catalytic activity that can enhance the overall reaction efficiency.
The electrocatalyst at the cathode can be made from any catalytic material capable of reducing CO2. The choice of electrocatalyst affects the end products of reduction. As reported by Jitaru (“Electrochemical Carbon Dioxide Reduction—Fundamental and Applied Topics (Review),” J. Univ. Chem. Tech. & Metallurgy, 42(4), 333-44, 2007), in aqueous solution, In, Sn, Hg, and Pb favor production of formic acid; Zn, Au, and Ag favor production of CO; metallic Cu favors production of hydrocarbons, aldehydes and alcohols. In non-aqueous solutions, Pb, Tl, and Hg favor production of oxalic acid; Cu, Au, Ag, In, Zn, and Sn favor production of CO and carbonates; Ni, Pd, and Pt favor production of CO; Al, Ga, and Group VIII elements (other than Ni, Pd, and Pt) favor formation of both CO and oxalic acid. The choice of pH and electrolyte can further create a bias toward particular reduction products. The present invention is not limited to a particular electrocatalyst, although Cu will be used as exemplary, because it generally favors production of hydrocarbons such as CH4. One skilled in the art can readily determine which electrocatalyst provides the particular reduction products desired.
In some embodiments, the cathode further comprises a photosensitizer that enhances the chemical reduction of CO2. In these embodiments, the overall system configuration allows at least a portion of the incident light to illuminate the cathode. For example, while most of the available light can be directed to illuminate the photoanode, parts of the iPVEC can be generally made sufficiently transparent that a portion of the light passes through the photoanode and intervening structures to illuminate the cathode as well. Examples of suitable photosensitizers include intrinsically conducting polymers that exhibit photosensitivity, as well as fullerenes, carbon nanotubes, and graphene. Graphene can be easy to process and can provide mechanical strength. Intrinsically conducting polymers are also easy to process. Particular polymers can be selected based on their band gap, for example, a band gap that allows visible light absorption. In some embodiments, polythiophene can be selected as a suitable photosensitive and conductive polymer. Other conductive polymers include poly(phenylenevinylenes) (PPVs), cyano-modified PPVs (CN-PPV, e.g., poly(2,5-di(hexyloxy)cyanoterephthalylidene, poly(5-(3,7-dimethyloctyloxy)-2-methoxy-cyanoterephthalylidene), methoxyethylhexyloxy-modified PPVs (MEH-PPV, e.g. poly[2-methoxy-5-(2-ethylhexyloxy)-1,4-phenylenevinylene]), phthalocyanines, and polyacetylenes. These materials are available in a range of molecular weights which can be selected for convenience in processing. Cathode materials can also provide scavenging of light with wavelengths that are not otherwise absorbed.
Proton-Conducting Medium
The proton-conducting medium can be a liquid or solid electrolyte. A conventional aqueous electrolyte can be used. Pure water has limited proton-conductivity due to the limited density of (solvated) protons. In some embodiments, an aqueous solution of a salt such as KCl can be used as the proton-conduction medium. In some embodiments, the proton-conducting medium comprises one or more of Na2SO4, KHCO3, or KOH. Salts such as KHCO3 can also provide a buffer function, with or without a separate salt. Without a buffer, local proton concentration and proton gradients may slow the proton conduction mechanisms by allowing accumulations of regions of space charge. A buffer can help minimize such effects. The pH of the electrolyte is not critical, but the buffering process can be more effective when the electrolyte is at least slightly basic (pH>7.0).
Solid electrolytes typically include polymers having exchangeable proton sites, for example, polysulfonates. In some embodiments, the solid electrolyte is NAFION® (DuPont), a sulfonated tetrafluoroethylene based fluoropolymer-copolymer. NAFION is one of a class of synthetic polymers with ionic properties resulting from the incorporation of perfluorovinyl ether groups terminated with sulfonate groups onto a tetrafluoroethylene backbone. As noted above, a desired property of the proton-conducting medium include is that it is permeable to protons while being impermeable to electrons (i.e., it is an electrical insulator), and is impermeable to oxygen and other larger atoms and molecules. The solid electrolyte can comprise bound water molecules and act as a conduit for supplying water (via diffusion through the layer) to the photoanode.
In some embodiments (as in
Photoelectrochemistry of the iPVEC
The photoelectrochemical process in the iPVEC can be viewed as starting with the generation of photoelectrons (e−) in the conduction band and holes (h+) in the valence band of the photoanode semiconductor. The electrons are allowed to flow to the cathode which is located on the far side of a proton-conducting medium. The holes generated at the photoanode react with water molecules supplied to the device to generate oxygen gas and protons (H+):
4h++2H2O (liquid)+hν→O2 (gas)+4H+ (5)
Eq. (5) now replaces Eq. (4). The redox potentials for Eq. (3) and Eq. (5) are +0.169 V and −1.23 V (CRC handbook) respectively. Gaseous oxygen evolves at the photoanode, while protons migrate to the cathode through the proton-conducting medium. The protons and electrons trapped by the Cu react with CO2 supplied at the electrocatalytic cathode, resulting in CO2 reduction products such as methane, ethane, formic acid, etc., depending on the catalyst present at the cathode. Equation (3) describes one reaction for a Cu cathode electrocatalyst as for the electrochemical cell. As noted above, the electrochemical cell can be optimized for a variety of different reduction products as desired. The energy for both the direct photocatalytic splitting of water and the power provided to drive the electrocatalytic reduction of CO2 is provided by light as long as the photoanode reaction can provide the necessary net redox voltage.
With reference to
The iPVEC provides a self-modulated device structure that can lead to increased CO2 conversion efficiency. When using solar light, the intensity and illumination angles change during the day. Photoelectrochemical or photocatalytic reactions that depend on light absorption thus have constant shifts in efficiency throughout the day, and it can be challenging to adjust the external voltage applied to a conventional PEC to optimize the absorption and conversion efficiency. In an iPVEC, the electrons generated at the photoanode supply the power to drive the electrocatalytic reduction of CO2 at the cathode. No external controls or adjustments are required. The iPVEC is self-modulated by the light absorption and the ongoing chemical reaction (chemical potentials specific to the composition and concentration of the anode and cathode materials). If the supply of CO2 is interrupted, hydrogen gas is produced. The supply of CO2 modulates the reaction products, and the production of CH4 relative to H2 can be controlled by CO2 availability. Similarly, additional materials such as NH3 or H2S can be used instead of H2O; treatment with the iPVEC can be used to remove these materials.
Depending on the particular installation, an iPVEC device can be optimized in different ways. As noted above, the electrocatalyst and optional photosensitizer at the cathode can be selected to change the mix of CO2 reduction products. The geometry can be modified to adapt to the available sources of light, water, and CO2. Large planar designs and arrays of flat panels can be used in a manner similar to solar cell arrays on rooftops and in fields. An installation designed to reduce CO2 from an exhaust pipe or smoke stack can have a tubular geometry (e.g., a honeycomb design) or other complex geometry designed to maximize the surface area of electrocatalyst exposed to the available CO2. The O2 produced at the photoanode can either be collected or vented. The methane or other reduction products can be used immediately as a fuel or collected in a storage tank or absorbing medium such as a bed of zeolyte beads. Tracking mechanisms and light concentrating devices, such as imaging and non-imaging lenses and reflectors, can be used to increase the total available flux of light delivered to an iPVEC. If natural light is unavailable, artificial light from any available source (such as arrays of LEDs, fluorescent tubes, and the like) can be used. The use of artificial light requires an external power source, but if the primary motivation for using the device is CO2 reduction, then using only solar energy is not a necessary constraint.
Methods of Preparing iPVECs
Methods of preparing iPVECs are also disclosed. In some embodiments, a thin film sandwich design is provided, wherein a photoanode is formed adjacent to a proton conducting medium on which is also formed an electrocatalytic cathode.
The device is adapted to provide contact between water and the anode and CO2 and the cathode. In some embodiments, the photoanode is formed on a porous transparent material such as ITO, and contact with water is provided through the porous material, which also allows evolved oxygen to exit from the vicinity of the photoanode and can be collected or allowed to diffuse away. The thin film depositions are can be prepared using techniques such as Langmuir-Blodgett films, electrophoretic deposition, dip coating and in-situ colloidal depositions, depending on the materials, which are known to those in the art.
Methods of Using iPVECs
Methods for reducing CO2 are disclosed, wherein the methods comprise providing an iPVEC, exposing the photoanode to water and photons such that water is split into electrons, protons, and oxygen at the photoanode, reducing CO2 electrocatalytically at the cathode using the electrons generated at the photoanode. The electrons from the photoanode are supplied on demand to the cathode at a potential sufficient to drive the electrochemical reduction of CO2 at the cathode.
In some embodiments, the iPVEC comprises a photoelectrochemical cell with two electrodes comprising a photoanode and a cathode, with a proton-conducting medium disposed between said two electrodes. The water can be supplied as liquid water or water vapor.
The photoanode of the iPVEC is supplied with an oxidizable protonated material (gas or liquid), which can be any material that can be oxidized at the photoanode illuminated with sunlight. Water may be used as an oxidizable material, and the resulting oxidized product is oxygen (gas). In some embodiments, the oxidizable material can be ammonia, hydrogen sulfide, etc. The iPVEC is also supplied with a reducible material, such as CO2. Protons produced as a result of oxidation diffuse across the proton-conducting medium to the cathode for use in reduction of products. However, in the absence of CO2, the protons and electrons can recombine to produce hydrogen at the cathode.
Applications and Advantages
The novel structures described herein can be utilized to implement device designs of iPVECs for CO2 conversion, using light (e.g., solar or LED illumination) as the sole power source, using low cost, scalable solution fabrication device processes, and non-toxic thin film materials for high efficient electrical transport and solar absorption. The devices and methods can operate at room temperature, ambient pressure reaction conditions and using inexpensive catalysts.
Thin film devices can be formed with large surface areas, and can be adapted to chimney filters, or to catalytic converters. The power source can be solar energy or a high efficiency light source such as an LED array. The reduction products can be used as a fuel for fuel cells, power plants, vehicles, rockets, etc., or to generate carbon-containing compounds for use as feedstock for other industrial synthetic processes. The only other by product, O2, is useful and can be easily collected. For a smokestack, the geometry can include a set of tubes parallel to the CO2 gas flow. In some embodiments, the geometry could include a “honeycomb” sort of filter, and several filters could be placed sequentially downstream of the gas to further filter any CO2 not converted by upstream filters. In some embodiments, several filters, consisting of corrugated-shaped iPVECs, can be suspended parallel to the CO2 gas stream, and sequential sets of filters can be disposed for further processing of the gas.
While layer thicknesses in most embodiments are generally small, the layers need not be planar. Cylindrical geometries can be used with either the anode or cathode on the inside of the cylinder (depending on the location of the light source). In some embodiments, more complex geometries, with the layers folded in various ways to create more surface area in a compact volume, can be implemented.
The iPVEC can be used for CO2 greenhouse gas reduction or neutralization. It can also be used as part of a life support system, for example, in a spacecraft, space station, undersea habitat, or personal life support system to replace or supplement CO2 scrubbers. An iPVEC allows ready reconversion of fuels for reuse, without using high temperature, expensive noble metal catalysts, or high pressure reaction conditions. The methods and devices are expected to be particularly useful in the Martian environment and to support exploration of Mars. CO2, H2O and sunlight are plentiful as raw materials. Oxygen and fuels can be manufactured on site to provide both life support functions and fuel.
The device can be prepared using low-energy manufacturing methods at ambient temperatures and with low materials cost. The device can also be made extremely compact, flexible, efficient, and uses solar energy as the only power source.
Further advantages and applications include the ability of the methods and devices to work at low temperatures, without requiring high temperature processes. Additionally, the methods and devices utilize low cost materials and methods, avoiding the use of expensive noble metal as catalysts and high pressure reaction conditions.
Details with respect to the present invention will be further described by way of following examples to illustrate aspects of this invention, which examples are not intended to limit the scope or applicability of this invention.
An electrochemical cell was constructed with an adaptation of laminar flow microfluidic testing (Brushett et al., 2009 and Whipple et al., 2010). The test platform consisted of a TEFLON® flow channel for the CO2 gas stream and an acrylic flow channel for the liquid electrolyte stream (See
A non-porous photoanode was used to allow cathode studies independent of the complexities of the PVC anode in the complete iPVEC device. The non-porous photoanode was fabricated by growing TiO2 nanowires on an indium tin oxide (ITO) conductive layer coated onto a glass substrate. The electrolyte channel was 4 mm thick and had a flow channel approximately 5×20 mm machined through the entire thickness. The exposed area (˜1 cm2) of this flow channel thus determined the total active area of the cathode and anode layers above and below the channel.
TiO2 nanoparticles, nanowires and nanotubes, as well as WO3 and ZnO nanowires, were synthesized using various solution processes as detailed below. The diameters ranged from 500 nm to 15 μm. The height-to-diameter aspect ratio (around 10:1) of the nanowires was varied by controlling the reaction conditions. In addition, density could be adjusted through Langmuir Blodgett monolayer assembly, dip coating, and spin coating on the appropriate electrode substrates.
TiO2 nanotubes were grown on an ITO film using potentiostatic anodization. Fluorine doped Tin-Oxide coated glass can be also used in place of ITO coated glass. The TiO2 nanotubes had an average length of 15 μm, an average outer diameter of 100 nm (inner diameter can be varied from 30 nm to 80 nm with growth conditions), and a higher surface area than nanowires, superior electrocatalytic properties and superior optical stability. The pristine nanotubes were annealed at 400° C. to convert amorphous TiO2 to anatase (confirmed by Raman analysis) for higher photocatalytic responses.
TiO2 nanowires were also grown via a hydrothermal process, adapted from (Wang, Y. et al., 2008 Electrochimica Acta 53, 7863) using sodium hydroxide and ethanol. The nanowires were dried in a furnace at 80° C., and annealed at 450° C. in air for an additional two hours.
The nanowire and nanotube assemblies were characterized by a variety of techniques to measure optoelectronic properties. Raman, FTIR and UV-visible spectroscopies were used to monitor every batch of materials to ensure structural and composition reproducibility. Atomic force microscopy and scanning electron microscopy (SEM) plus electrochemical and four-point probe resistance measurements were performed to characterize electron transport.
Raman and FTIR spectra indicated that the TiO2—WO3 nanocomposites contain the same crystal structures as their component materials. UV-Vis absorption spectra and the I-V characteristics of TiO2 nanowires and TiO2—WO3 composite showed improved light absorption and mobility in the respective composites with respective sulfite and iodine electrolytes by standard four probe I-V measurements. Both improved over the individual constituents in photocurrent and most importantly, CO2 conversion efficiency. Electron dispersive X-ray spectroscopy (EDS) and SEM imaging showed that the nanocomposites exhibited uniform assembly.
The cathode was built from commercially available, electrically conductive, GDL substrates such as TORAY® carbon paper or SIGRACET® graphite GDL which ranged in thickness from 100 to 400 μm. These are available with varying amounts of polytetrafluoroethylene (PTFE) to yield varying hydrophobicity. Copper electrocatalysts were deposited on the GDL by electrodeposition (electroplating). Once deposited, the electrode assembly was annealed under a hydrogen atmosphere to reduce the nitrate salt to copper nanoparticles. The copper cathode was paired with a standard platinum-based anode prepared in a similar manner (created with platinum-black nanoparticles). This type of anode has a well-documented performance and served as a reliable counter electrode without introducing additional electrochemical limitations.
The electrochemical cell of Example 1 combined with the electrodes described above allowed for an evaluation of the performance of cathode materials and provided a system for evaluating electrolytes. A SRI 8610D gas chromatography (GC) system with a thermal conductivity detector (TCD) was used in addition to IR gas analysis for characterization of gaseous reduction products. The GC column was chosen to separate many of the lighter compounds produced by CO2 reduction. An acceptable separation was achieved with a helium carrier gas pressure of 50 psi and the following column temperature ramp: 40° C. for 2 minutes, then an increase of 10° C./min to 150° C. which was then held for 2 minutes.
SEM imaging directly after fabrication compared to after electrochemical CO2 reduction show the Cu catalyst surface develops nano-scale pits and cracks thereby increasing its surface area for catalytic activity.
The electrocatalyst, GDL and photoelectrode materials were investigated separately using an electrochemical liquid cell and a photochemical catalysis dry cell. The three-electrode cell in the electrochemical catalysis was made gas tight with an outlet directly to the IR gas analysis cell for detection of methane or other hydrocarbon reduction products. A separate gas outlet was provided for the Pt counter electrode to prevent oxygen produced there from diluting the gas stream containing the reduction products. A strip of copper foil or painted or electrodeposited Cu catalysts was used for the working electrode. CO2 was bubbled through the solution at high flow rates prior to the electrolysis to purge most of the oxygen and nitrogen from the cell. The CO2 flow was then reduced to approximately 2 sccm and the Cu working electrode was kept at −2 V for at least 6 min. This working electrode typically produced currents of roughly 160-170 mA.
In the photocatalysis dry cell, a Hoya-Schott EX-250 UV source was used at a 10-15 cm distance from the sample through a quartz view port, CO2 was bubbled through deionized water in an otherwise sealed chamber for 15 minutes. The exit valve was sealed after an additional minute. Gas (500 μL) was analyzed within a few minutes of light exposure. The GC analysis of composition and concentration was calibrated with gas standards, and confirmed by spectroscopy analysis data. Photocatalysis offers high selectivity for CH4, with a small amount of C2H6. Like any gas-solid interaction, the yield is not as high as for electrocatalysis in a liquid cell, where predominant C2H4 and C2H6 were produced, as well as H2. The comparisons of fuel production and energy conversion efficiency photocatalysis and electrocatalysis are listed in Table 1.
TABLE 1
Fuel production and energy conversion
efficiency for photocatalysis and electrocatalysis
Photo-
Electro-
catalytic
catalytic
Cu Loading (mg/cm2)
0.01
5
Input Power (mW)
20
77
Rate
Eff.
Rate
Eff
(mL/h)
(%)
(mL/h)
(%)
Hydrogen
0
0
10.6
45
Carbon Monoxide
0
0
0.3
1
Methane
0.09
7
0
0
Ethane
0.01
2
0.1
2
Ethylene
0
0
0.2
4
Total Efficiency (%)
9
52
The optical to chemical energy conversion efficiency is defined by (Law et al., 2005)
Optical conversion efficiency(percent)=100IcFi[(ΔG/n)−Vb]/W (7)
where Ic is the current density (mA/cm2), W (mW/cm2) the incident light intensity, ΔG (V) the standard free energy of formation of the products, n the number of moles of the product for one mole of CO2, Vb the bias voltage between the photocathode and the counter electrode, and Fi the Faraday constant. Both Ic and Vb were expected to depend on the electrode materials used. In addition, dynamic photo current was measured to optimize overall impedance. The energy efficiency of the electrochemical reduction process was calculated using the following equation:
where η is the energy efficiency, ΔHj,comb is the heat of combustion of species j in J/mol, nj is the molar flow rate of species j in mol/s, i is the reduction current in amperes, Vapplied is the potential of the cell during reduction in volts, and Veq is the open circuit equilibrium potential of the cell in volts. At these particular reduction conditions, this Cu cathode was approximately 52 V energy efficient in the creation of gaseous reduction products. Hydrogen production accounts for almost 45 percent of the energy used, ethylene 4 percent, ethane 2 percent and CO2 1 percent.
A light beam (e.g., solar or LED), with wavelength range 260 nm≦λ≦600 nm (or 700 nm≦λ≦1500 nm, if a quantum dot of PbS is used for the photosensitive element), is concentrated and directed at an assembly of TiO2 nanostructures (e.g., nanowires or nanotubes) that define one or more dissociation channel, as illustrated in
The TiO2 nanostructures are doped with WO3 and/or PbS quantum dots and/or with CdS and/or CdSe and/or CdTe and/or ZnO2 and serve as a photocatalyst. The interstices between adjacent TiO2 nanostructures contain the H2O vapor. The light beam and nanostructures interact, dissociate the water molecules, and liberate H+ and e− according to reactions such as that of Eq. (6).
The O2 is drawn off and may be used for other purposes. Many of the H+ ions pass to a second end of a dissociation channel, which serves as a first electrochemical cell electrode (ECE), that is a GDL such as Toray Paper. The dissociation channel(s) and first and second channel ends serve as a photoanode. Electrical charges on the H+ ions are electrochemically transferred via a proton-conducting electrolyte or membrane (e.g., NAFION® or Na2SO4 or KHCO3 or KOH), having a preferred thickness of 1-20 μm, and are received at a cathode (second ECE) comprising Cu or Co nanoparticles or Cu passivated with polyvinylpyrrolidone (PVP) and/or nanoparticles of Au and/or Ag. The Cu or Co nanoparticles are optionally distributed over a gas diffusion layer (GDL), which may comprise carbon paper (e.g., Toray paper) and a hydrophobic binder (e.g., TEFLON®). The first and second ECEs plus the membrane serve as an electrochemical cell.
A non-zero chemical potential ΔCP, with a value of about +0.5 eV, develops between the first and second ECEs and serves to direct the H+ ions and/or the electrons toward the second ECE. CO2 molecules are provided adjacent to the second ECE for reduction to produce hydrocarbons. The second ECE optionally includes a graphene sheet coated with Cu or Co molecules distributed thereon.
Electrons are generated by photodissociation of TiO2 (optionally loaded with PbS, CdSe and/or CdTe, at the photoanode) and are transferred to the second ECE via the electrolyte where they support conversion of CO2 to hydrocarbons, such as CH4, C2H6 and C2H4, by redox reactions such as that of Eq. (5) with an estimated branching ratio of about 10 percent. The particular redox reaction at the Cu electrode will depend on the chemical potential associated with the photoanode output. The Cu or Co that comprises the second ECE is provided as nanoparticles, preferably “nanopolygons,” which are m-sided polygons (e.g., m=4, 5, 6) and initially have sharp edges. Optionally, the second ECE comprises a photosensitizer, such as polythiophene and/or its derivatives, to produce additional H+ ions. A nanocube morphology serves as the most active catalytic site(s) to receive and temporarily hold one or more CO2 molecules and H+ ions to promote reduction of CO2 by redox reactions such as the reaction in Eq. (3), which also produce ethylene (C2H4) and ethane (C2H6), with estimated branching ratios of about 4 percent and 2 percent, respectively. The fraction of hydrocarbons are estimated and are collected at or near the second ECE, for immediate or subsequent use as fuel, and the H2O molecules are drawn off and used for other purposes. The percentage composition of different hydrocarbon species produced depends upon the catalyst morphology. As the hydrocarbons are produced at the second ECE, these substances are drawn off and received at a porous assembly of aluminosilicate molecules (e.g., ZEOLITE®). The adjacent CO2 molecules are not absorbed as readily by the aluminosilicate assembly and are primarily dispersed in the ambient medium, rather than being received and held on surfaces of the aluminosilicate assembly. Periodically, the aluminosilicate assembly with the hydrocarbons absorbed thereon is removed and replaced by a “clean” aluminosilicate assembly.
The H+ and e− particles do not require use of a battery for transport to the cathode (ECE2), and the EC chemical potential is believed to provide energy potentials for the H+ and e− particles that include values between −1.23 eV and +0.169 eV, which are redox potentials P for reduction of CO2. The redox potentials for formation of C2H2 or C2H4 have similar redox values.
The invention disclosed here uses a light source, but no battery or other source of electrical power, to reduce CO2 molecules and to provide one or more species of hydrocarbon molecules. Where a light concentrator is used, localized heating from this light is sufficient to initiate the subsequent reactions, at ambient (room) temperature. Solar or LED light can be used here, Provision of temperatures as high as T=1600° C., which is often required in a conventional approach to CO2 reduction, is not required in the disclosed invention. Local pressure at or even below atmospheric pressure is sufficient for the disclosed invention. Use of expensive and toxic catalysts, such as Pt or Pd, is not required here. A source of H2O molecules replaces a hydrogen supply that is conventionally required. Use of H2O rather than H2, also improves the associated photon efficiency, to an estimated 10 percent for hydrocarbon production, for the disclosed process. Use of an integrated photoanode and electrochemical cell, with only three distinct electrodes, provides further efficiencies.
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